JP6023498B2 - Extrusion molding apparatus and method for manufacturing cylindrical elongated body - Google Patents

Description

In the present invention, when a resin coating layer is formed on the outer periphery of a core material made of a solid or hollow cylindrical body, an extrusion capable of continuously forming a flow path along the axial direction in the resin coating layer. The present invention relates to a molding apparatus and a method for producing a cylindrical elongated body having a flow path along the axial direction in a resin coating layer constituting the outer periphery of the core material, and belongs to a resin molding technique.

  When forming a resin coating layer on the outer periphery of a core material made of a solid or hollow cylindrical body, a flow path for passing a fluid such as gas or liquid along the axial direction of the core material in the resin coating layer Cables, hoses, tubes, and the like that are continuously formed have been used for various purposes so far, and various proposals have been made regarding their usage and molding methods.

For example, Japanese Unexamined Patent Application Publication No. 2010-117433 (Patent Document 1) discloses a plastic optical fiber cable suitable as a short-distance communication wiring in a moving body such as an automobile, an aircraft, a ship, and a train.
The structure is a three-layer structure in which a coating inner layer and a coating outer layer are provided with a polyamide-based resin on the outer periphery of a plastic optical fiber serving as a core material.
The forming method uses an extrusion coating apparatus equipped with a nipple and a die, and specifies and shapes the shape and arrangement of the die and the nipple, particularly the tip position of the nipple.

Japanese Patent Laid-Open No. 11-86656 (Patent Document 2) proposes a flat vinyl insulated vinyl sheath cable (VVF).
Specifically, in order to prevent the sheath from biting into the valleys between the insulated wires when extruding and forming a sheath having an elliptical cross section on the outer periphery in which a plurality of insulated wires are arranged in parallel. A sheath is formed by tube extrusion at the tip of the nipple having a passage through which a plurality of insulated wires are inserted in parallel, by tube extrusion at the valley of the insulation wire, and by solid extrusion at the other portion.

  Furthermore, in JP 2009-127850 A (Patent Document 3), as a hose for an automobile such as an oil hose, a cooling water hose, a gas hose, etc., in addition to a tube-shaped central flow path, A hose in which a second flow path is formed in the peripheral wall portion is disclosed.

  The automotive hose described in Patent Document 3 includes a nipple and a substantially cylindrical die that is provided coaxially with the nipple, with a gap on the outer periphery of the nipple. A pair of upper and lower protrusions having a complicated shape such as a cross-section having a triangular shape for forming a second flow path, which includes an extrusion head for extruding an extrusion material from the gap between the two and forming a tube shape Is positioned in the gap between the nipple and the die, and the tip portion thereof is positioned in the vicinity of the tip opening of the die. It is.

In order to form the second flow path inside the outer peripheral wall in Patent Document 3, a complicated structure such as providing a flow path for introducing air into the protrusion is inevitable.
In addition, this Patent Document 3 has a description that the protrusion may be formed integrally with the nipple and extend from the outer peripheral surface of the nipple to the vicinity of the tip opening of the die. It is not disclosed in what state the nipple is formed.

On the other hand, the applicant has proposed an ultrafine liquid supply body used for writing instruments and cosmetics in Japanese Patent Application Laid-Open No. 2012-16931 (Patent Document 4).
This liquid supply body has a core for guiding the liquid and a skin body provided around the core, and the core and the skin body are formed integrally.
The outer skin surrounds the outer periphery of the core from the tip of the core to the liquid holding portion, and passes through the cylindrical wall of the outer shell in the axial direction to hold the liquid from the tip of the core. At least one air hole extending into the portion is formed.

  Here, the extrusion molding apparatus for forming the resin coating layer on the outer periphery of the conventional core material will be specifically described with reference to FIGS. 13 and 14.

  As shown in FIGS. 13 and 14, the conventional extrusion molding apparatus 1 includes a crosshead 5 holding a cartridge 4 containing a nipple 2 and a die 3, and a front end portion of the cartridge 4. It comprises a cap 6 for fixing the die 3.

  In the extrusion molding apparatus 1 having such a configuration, the cross head 5 has a resin inlet 5a for supplying resin R from an extruder (not shown) to the inside.

  Therefore, in order to form a resin coating layer on the outer periphery of the solid or hollow core material 7 using this extrusion molding apparatus 1, the core material 7 is placed inside the nipple 2 in the direction of the arrow as shown in FIG. The resin R supplied from the extruder is supplied into the crosshead 5 from the resin supply port 5a in a state where the tip portion is located in the resin discharge hole 3c formed in the die 3.

The supplied resin R is sent to the inside of the cartridge 4 as shown in FIG. 13 and flows along the outer periphery of the nipple 2.
Accordingly, by drawing the core material 7 from the resin discharge port 3a of the die 3 at an appropriate speed, the resin R adheres to the outer periphery of the core material 7 in the resin discharge hole 3c of the die 3 or in the immediate vicinity thereof. layer R ¹ can be manufactured tubular elongate body 8 formed integrally.

JP 2010-117433 A (Claims) Japanese Patent Laid-Open No. 11-86656 (Claims) JP 2009-127850 A (Claims) JP 2012-16931 A (Claims)

Regarding the liquid supply body described in Patent Document 4, the applicant of the present application has been manufactured by various methods with reference to the prior art.
However, in the method following the conventional technique, it is difficult to efficiently obtain a liquid supply body when manufacturing a liquid supply body having excellent characteristics, in particular, a liquid supply body having a small diameter.

More specifically, in the conventional manufacturing method, the flow path is formed in the outer layer of an extremely thin cylindrical elongated body having a cross-sectional diameter of 10 mm or less, particularly 2 to 4 mm, in particular. Was inherently difficult.
In other words, in order to obtain a long cylindrical body having an extremely narrow flow path, not only precise preparation is required for the dies and nipples constituting the extrusion molding apparatus, but also precise setting is required in the assembly of the extrusion molding apparatus. It is.

Furthermore, in the conventional extrusion molding apparatus, the structure itself must be complicated, for example, it is necessary to provide a special hole for introducing air into the die or nipple.
In addition, the gap between the inner circumference of the die and the outer circumference of the nipple is extremely narrow, making it difficult to respond to changes in the resin material to be coated and changes in the resin lot, and the relationship between the resin material and the resin lot and the product obtained In correspondence, it was difficult to arbitrarily change the cross-sectional size of the core material and the flow path of the second fluid.

  In view of such problems, the present invention eliminates the need for strict setting when forming a resin coating layer having a flow path on the outer periphery of the core material, and requires a complicated structure such as air holes in a die or nipple. An object of the present invention is to provide an extrusion molding apparatus that can arbitrarily change the size of the cross section of the flow path.

Furthermore, by the extrusion molding apparatus, the size of the cross section of the flow path is arbitrarily changed according to the application, and a cylindrical long body having a flow path of gas or liquid having a desired cross-sectional area, particularly a fine diameter An object of the present invention is to provide a method for producing a cylindrical long body having a cylindrical shape.

In order to achieve the above object, the invention according to claim 1 of the present invention provides:
A crosshead, a cartridge mounted in the crosshead, a nipple housed in the cartridge, a die housed in the cartridge and receiving a tip portion of the nipple, and a reciprocating engagement with the cartridge An extrusion molding apparatus for forming a flow path in a resin film constituting an outer layer of a core material, comprising an adjustment cap,
The dice
A frustoconical tip portion of the nipple can be received and has a space for forming a resin coating layer, and a small-diameter resin discharge hole is formed coaxially with the nipple at the center portion of the closed end surface,
The nipple is
While having a cylindrical body that can be fitted in the resin discharge hole formed in the die at the tip of the truncated cone-shaped reduced diameter portion continuous to the hollow cylindrical nipple body having a core material insertion portion inside , Having a slit for forming one or a plurality of ribs from the end face of the cylindrical body toward the truncated cone side,
The adjustment cap is
It is possible to adjust the positional relationship between the nipple and the die, and is in the shape of a cap nut having a core material insertion portion at the center,
By adjusting the positional relationship between the nipple and the resin discharge hole of the die that receives the nipple , the amount of resin flowing in the slit is adjusted, and a gap for forming a fluid flow path from the tip of the rib It is the extrusion molding device characterized by comprising so that a part may be formed.

The invention according to claim 2 of the present invention is
In the extrusion apparatus of Claim 1,
The dice
A conical inner peripheral surface capable of forming a resin flow path is formed between the frustoconical tip of the nipple.
It is characterized by.

The invention according to claim 3 of the present invention is
The extrusion apparatus according to claim 1 or 2,
The rib is
The air flow path which makes air circulation favorable is formed in the internal peripheral surface, It is characterized by the above-mentioned.

The invention according to claim 4 of the present invention is
The extrusion apparatus according to claim 1 or 2,
The cylindrical body is
A resin flow path that improves the flow of the resin is formed on the outer peripheral surface of the base of the slit.

Further, the invention according to claim 5 of the present invention is
Single or plurality of slits coating resin flows is formed, the position of the die having a resin discharge hole for receiving the tubular portion and the nipple having a diameter of the tubular body, the tip of the cartridge containing the die The cross section of the fluid flow path provided in the resin coating layer of the outer layer of the core material by rotating and adjusting the adjustment cap that is screwed into the part and disposed on the outlet side of the resin discharge hole of the die It is the manufacturing method of the cylindrical elongate body characterized by controlling the magnitude | size of this.

The invention according to claim 6 of the present invention is
In the manufacturing method of the cylindrical elongate body of Claim 5,
The cylindrical elongated body is
The cross-sectional diameter is ultra-fine with 2 to 4 mm.

The invention according to claim 7 of the present invention is
In the manufacturing method of the cylindrical elongate body of Claim 5 or 6,
The flow path is
The cross-sectional area is in the range of 0.01 to 0.15 mm ² .

In addition, this invention includes the following invention as another form.
1) An extrusion molding apparatus for forming a flow path in a resin film constituting an outer layer of a core material,
The nipple constituting the extrusion device is:
A narrow cylindrical body attached to the tip of the truncated cone-shaped reduced diameter portion is provided with a slit for forming one or more ribs parallel to the axis of the nipple from the end surface to the reduced diameter portion side. It was
By adjusting the positional relationship with the resin discharge hole of the die that receives the cylindrical body, the amount of resin flowing in the slit is adjusted, and a gap portion for forming a fluid flow path from the tip of the rib is formed. Configured to form
An extrusion apparatus characterized by the above.
2) An extrusion apparatus for forming a flow path in a resin film constituting the outer layer of the core material,
A cross head, a cartridge mounted in the cross head, a nipple housed in the cartridge, a die for receiving a tip portion of the nipple, and an adjustment cap engaged with the cartridge.
The dice
The frustoconical tip of the nipple can be fitted and has a space for forming a resin coating layer, and a small-diameter resin discharge hole is formed coaxially with the nipple at the center of the closed end surface. ,
The nipple is
A cylindrical body that can be fitted into a resin discharge hole formed in the die is provided at the tip of the truncated cone-shaped reduced diameter portion that is continuous with the cylindrical nipple body, and the cone is formed from the end surface of the cylindrical body. A slit for forming one or a plurality of ribs is formed toward the base side,
The adjustment cap is
It is possible to adjust the positional relationship between the nipple and the die, and is in the shape of a cap nut having a core material insertion part at the center.
An extrusion apparatus characterized by the above.
3) In the extrusion molding apparatus according to (1) or (2) above,
The rib is
An air flow path that improves air passage efficiency is formed on the inner peripheral surface.
It is characterized by.
4) In the extrusion molding apparatus according to (1) or (2) above,
The cylindrical body is
The resin flow path which improves the contact efficiency of a core material and resin is formed in the base outer peripheral surface of the said slit.
It is characterized by.
5) The position of the nipple having a thin cylindrical body with one or a plurality of slits through which the coating resin flows and the die having the resin discharge hole for receiving the cylindrical portion are linked with the cartridge of the crosshead. And controlling the size of the cross section of the flow path of the fluid provided in the resin coating layer of the outer layer of the core material by adjusting while rotating the adjustment cap arranged in front of the die.
The manufacturing method of the cylindrical elongate body characterized by these.

  The extrusion molding apparatus according to the present invention includes a cylindrical body that can be fitted into a resin discharge hole formed in a die at a tip portion of a truncated cone of a nipple body having a core material insertion portion therein, and the cylindrical shape. Since it has a nipple in which a slit for forming one or more ribs is formed from the end surface of the body toward the truncated cone, a cylindrical length having one or more fluid passages on the outer periphery of the core material The scale can be manufactured very easily.

  This extrusion molding apparatus delicately defines the positional relationship between the nipple having the above-described configuration, a die having a resin discharge hole through which a cylindrical portion having a slit provided at the tip of the nipple can be inserted, and the nipple and the die. The main component is a cap nut-shaped adjustment cap that can be adjusted and screwed into the cartridge mounted on the crosshead, making the extrusion molding device simple, easy to handle, and extremely practical. It is expensive.

Furthermore, according to the extrusion molding apparatus of the present invention, for example, it is possible to form a flow path in the resin coating layer of the outer layer of an extremely fine core material having a cross-sectional diameter of 2 to 4 mm.
Furthermore, in the present invention, it is not necessary to form air holes for forming the flow path, so that the configuration can be made very simple.

  On the other hand, the manufacturing method of the cylindrical elongated body according to the present invention includes a nipple having a thin cylindrical body in which one or a plurality of slits through which a coating resin flows is formed, and a resin discharge hole that receives the cylindrical portion. The outer layer of the core material is controlled by controlling the amount of resin flowing in the slit by adjusting the position of the die with the cross head while rotating the adjustment cap arranged in front of the die. The cross section of the fluid flow path provided in the resin coating layer can be a desired cross section.

  In particular, in the method for manufacturing a cylindrical elongated body according to the present invention, the size of the flow path formed in the resin coating layer can be changed without replacing nipples or dies.

The cylindrical elongated body manufactured in the present invention has a flow path extending from the front end side to the rear end side of the outer coating resin layer formed around the core material. As a cosmetic or other gas-liquid supply body, the required fluid can be smoothly distributed.

1 is a partially cutaway cross-sectional view showing an example of an extrusion molding apparatus according to the present invention. It is a partially cutaway longitudinal cross-sectional view which shows the principal part before the assembly of the extrusion molding apparatus in FIG. It is a partially notched front view of the extrusion molding apparatus in FIG. It is sectional drawing which shows an example of the nipple in this invention. It is a front view which shows the other example of the nipple in this invention. It is a top view which shows the further another example of the nipple in this invention. It is explanatory drawing which shows the positional relationship of the nipple and die | dye in this invention. It is a cross-sectional view which shows an example of the cylindrical elongate body obtained with the extrusion molding apparatus of this invention. It is a cross-sectional view which shows the other example of the cylindrical elongate body obtained by this invention. FIG. 6 is a cross-sectional view showing still another example of the cylindrical elongated body obtained by the present invention, which is formed in a state where the adjustment cap shown in FIG. 3 is at a position of 0 °. FIG. 5 is a cross-sectional view showing still another example of the cylindrical elongated body obtained by the present invention, which is formed in a state where the adjustment cap shown in FIG. 3 is at a position of 90 °. FIG. 5 is a cross-sectional view showing still another example of the cylindrical elongated body obtained by the present invention, which is formed in a state where the adjustment cap shown in FIG. 3 is at a position of 180 °. It is a partially cutaway cross-sectional view of a conventional extrusion molding apparatus for forming a resin coating layer. It is a partially notched front view of the conventional extrusion molding apparatus for resin coating layer formation.

Hereinafter, an example of the implementation of an extrusion molding apparatus for molding a cylindrical cylindrical body having one or a plurality of flow paths on the resin coating layer formed on the outer periphery of the core material of the present invention, and utilizing this extrusion molding apparatus The manufacturing method of the cylindrical elongate body demonstrated concretely in detail based on drawing and an Example.
In addition, the same thing as the name shown in FIG.13, 14 is demonstrated as the same code | symbol.

  As shown in FIG. 1, an extrusion molding apparatus 11 according to the present invention has a resin introduction port 5a for receiving a resin R, and a nipple 2 and a die 3 for receiving the tip of the nipple 2 are incorporated therein. The crosshead 5 is configured to hold the cartridge 4, and the adjustment cap 12 is mounted on the outer periphery of the front end of the cartridge 4 protruding from the front end surface of the crosshead 5 so as to be freely advanced and retracted.

  In the extrusion molding apparatus 11, as shown in FIG. 4, the nipple 2 reduces the diameter of the distal end side (left side in FIG. 2) of a hollow nipple main body 2a having a core material insertion portion into a truncated cone shape. At the same time, a thin cylindrical body 2c is integrally formed on the end surface of the reduced diameter portion 2b.

  The cylindrical body 2c is capable of moving back and forth in the resin discharge hole 3a formed in the die 3, and has a length that is about one tenth of the length of the nipple 2. is there.

  As apparent from FIGS. 5 and 6, a slit S having a required width and depth is formed on the peripheral wall of the cylindrical body 2 c in parallel with the axis, thereby providing one or more cylindrical bodies 2 c. A rib 2d having a length shorter than the length is formed.

The end face shape of the rib 2d greatly affects the formation of the cross-sectional shape of the fluid flow path formed in the resin film constituting the outer layer of the core material. The cross-sectional shape is a sector shape, a circular shape, an elliptical shape, or the like. can do.
When the cross section of the rib 2d is fan-shaped, the length of the left and right short sides is about ½ of the length of the slit S, and when it is circular, about ½ of the length of the slit S. When the diameter is set to be an ellipse, the minor axis is preferably set to about ½ of the length of the slit S.

  The rib 2d is formed by a slit S having a required width parallel to the central axis of the cylindrical body 2c. When forming a plurality of ribs 2d, the slits S are equally spaced.

When the slit S is formed in the cylindrical body 2c, the resin amount can be controlled as the length (depth) of the slit S increases. However, the strength of the rib 2d to be formed is limited.
Therefore, if the rib 2d to be obtained is thin, it is difficult to process, and it is likely to be bent or deformed in practice.
Therefore, consideration must be given to the cross-sectional shape of the rib 2d obtained, the length of the side, and the like.

The slit S is for introducing the molten resin R into the cylindrical body 2 c of the nipple 2.
Therefore, while the resin touches the core material 7 by the positional relationship between the end surface of the rib 2d formed by the formation of the slit S and the resin discharge hole 3c provided in the die 3, the outer periphery of the core material 7 A second channel having a different cross-sectional size is formed in the formed coating layer.

In addition, as shown in FIG. 6, an air flow path 2e having an arcuate cross section is formed on the inner peripheral surface of the rib 2d in the axial direction in order to improve the air flow.
Further, a resin flow path 2f for improving the flow of the resin is formed on the outer peripheral surface of the cylindrical body 2c below the base end portion of each slit S.

The nipple 2 shown in FIGS. 4 to 6 has a total length of about 55.0 mm, an inner diameter of about φ6, and a cylindrical body 2c continuously provided on the distal end side of the reduced diameter portion 2b. Is approximately 3.0 mm, the outer diameter is approximately φ2.3, the inner diameter is approximately φ1.45, and the depth of the slit S formed from the end surface of the cylindrical body 2 c toward the reduced diameter portion 2 b is approximately 1.3 mm. Is.
In the cylindrical body 2c, five slits S having the depth are formed at equal intervals.

  The die 3 that engages with the nipple 2 having the above-described configuration has a conical inner peripheral surface on which the resin flow path 3a can be formed with the reduced diameter portion 2b of the nipple 2, and the top of the conical portion is positioned. A resin discharge hole 3 c is formed at the center of the closed end surface 3 b so as to be positioned on the axis of the nipple 2.

The resin discharge hole 3c has a diameter that can receive the cylindrical body 2c of the nipple 2. (See Fig. 2 and Fig. 7)
Therefore, the positional relationship between the resin discharge hole 3c and the cylindrical body 2c at the tip of the nipple 2, specifically, the position of the tip of the cylindrical body 2c relative to the resin discharge hole 3c, in other words, By adjusting how much the depth of the slit S provided in the cylindrical body 2c of the nipple 2 is adjusted, the size of the cross section of the flow path provided in the resin coating layer formed on the outer periphery of the core material 7 is adjusted. It can be adjusted.

The cartridge 4 has a screw 4a formed on the outer periphery of the tip.
On the other hand, the adjustment cap 12 that engages with the cartridge 4 has a cap nut shape, as is apparent in FIG. 2, and is formed on the inner peripheral surface of the outer periphery of the tip of the cartridge 4. formed screw 4a screwed to the screw 12 c is in the center of the closure surface, the insertion portion 12b for inserting the core member 7 in which the resin coating layer formed on the outer peripheral portion is opened.

  The adjustment cap 12 is formed with four notches 12a to be rotated by 90 ° on the outer peripheral surface thereof. For example, a wrench is engaged with these notches 12a and rotated counterclockwise. It is configured as follows.

In the adjustment cap 12 shown in FIG. 3, A is the position where the notch 12a is 0 °, B is the position where the notch 12a is 90 ° counterclockwise, and C is the notch 12a. Similarly, the position of 180 ° is indicated by D, and the notch 12a is also indicated by a position of 270 °.

Therefore, by rotating the adjustment cap 12 in the direction of the arrow as shown in FIG. 3, the adjustment cap 12 is brought into contact with the front surface of the crosshead 5 as shown by the arrow in FIG. Can do.
The positional relationship between the resin discharge hole 3a of the die 3 and the nipple 2 described later (more specifically, the cylindrical body 2c of the nipple 2) can be adjusted by the separation and contact of the adjustment cap 12 with respect to the cross head 5. Is.

  The adjustment of the positional relationship between the resin discharge hole 3c of the die 3 and the cylindrical body 2c of the nipple 2 is controlled by the pitch width of screws formed on the inner peripheral portion of the adjustment cap 12.

  The extrusion forming apparatus 11 according to the present invention having such a configuration includes a cylindrical elongated body 10 having a flow path for circulating a fluid in an outer layer, particularly an extremely thin cylindrical elongated body 10 having a cross-sectional diameter of 2 to 4 mm. It is particularly effective for manufacturing.

The material used for the cylindrical elongated body 10 may be any material that forms the outer layer as long as it is thermoplastic and can be extruded, including polyolefin resins, polyester resins, polyamide resins, and polyacetal resins. As such, thermoplastic resins are widely available.
Furthermore, various materials are applied as the core material 7, and a rod-shaped body, a hollow body, a fiber bundle, and the like can be used.

A method for forming the cylindrical elongated body 10 using the extrusion molding apparatus 11 will be specifically described.
First, as shown in FIG. 1, the nipple 2 is mounted in the cartridge 4 mounted in the cross head 5, and the die 3 is placed in front of the nipple 2 and the nipple 2 is inserted into the resin discharge hole 3c. The cylindrical body 2c is set so as to be received.
Thereafter, the adjustment cap 12 is screwed into the front end portion of the cartridge 3 to hold the nipple 2 and the die 3 on the cross head 5.

Next, resin R supplied from an extruder (not shown) is supplied into the crosshead 5 through the resin supply port 5 a of the crosshead 5.
The supplied resin R is supplied to the inside of the cartridge 4 through a flow path (not shown) formed in the outer peripheral portion of the cartridge 4, flows in the direction of the die 3 along the outer peripheral portion, and discharges the resin from the die 3. The outer periphery of the core material 7 drawn out to the hole 3c is covered with resin.

At that time, as described above, the nipple 2 of the present invention has a cylindrical body 2c having a narrow slit S and a rib 2d at the tip of the truncated cone-shaped reduced diameter portion 2b of the nipple 2. Yes.
However, as shown in FIG. 7, when the cylindrical body 2c is not inserted into the resin discharge hole 3c, or even if the tip of the rib 2d is close to the resin discharge hole 3c, the resin of the die 3 is used. When the tip of the rib 2d is not located within a certain range (distance) from the end face of the discharge port 3c, specifically, the adjustment cap 12 is positioned at a position D of 270 ° in FIG. In the case of the position of 75 mm, all the resin R is pushed out from the resin discharge hole 3c.
Therefore, as shown in FIG. 8, the resin R forms the primary coating layer R ₁ on the outer periphery of the core material 7, but does not form a flow path for passing air, liquid, or the like.

  However, when the tip of the rib of the nipple 2 is within a certain range from the end surface of the resin discharge port 3c of the die 3, the flow path FR is in contact with the outer periphery of the core material 7 as shown in FIG. And can be continuously formed along the axis of the core material 7.

Thus, in the present invention, the positional relationship between the nipple 2 and the die 3 is a very important factor.
Therefore, in the present invention, the positional relationship between the nipple 2 and the die 3, particularly the positional relationship between the tip position of the rib 2d formed at the tip portion of the nipple 2 and the resin discharge hole 3c of the die 3 is adjusted as described above. The cap 12 can be easily and easily controlled.

The flow path FR of the long cylindrical body 10 obtained by the present invention is basically formed in contact with the outer edge of the core material 7 as shown in FIG.
Therefore, if along the outer edge of the core member 7 does not form a flow path FR, once to form a primary coating layer R ₁ on the outside of the core member 7, accordingly then, outside the secondary coating of the primary coating layer R ₁ by forming the flow path FR simultaneously makes a layer R _2, it can form the channel FR in the center or near the coating layer.

Further, the flow path FR can change the amount of resin flowing in the cylindrical body 2c by controlling the cross-sectional shape of the rib 2d and the width and depth (depth) of the slit S.
Furthermore, the cross-sectional shape of the flow path FR can be easily changed by changing the cross-sectional shape of the rib 2d.

  The cylindrical elongated body 10 having the flow path FR along the axial direction in the resin film layer formed on the outer peripheral portion of the core material 7 thus obtained is a resin film with a specific color ink in the core material 7. By allowing other colors of ink to flow through the flow path FR formed in the layer, a two-color or multicolor writing instrument can be obtained.

Furthermore, it can be used as a cleaning tool for cleaning the inside of an elongated tube that inserts a handle of an ultra-fine brush into the middle of the core material and injects fluid such as water or air from the outer hole. it can. In that case, the core material is not a complicated capillary, but a shape close to a simple hole.
Furthermore, it can also be used as a cleaning tool such as a deep hole that ejects liquid from the center and vacuums it from a hole on the outer periphery to collect the liquid.

5 and 6, slits S having five required widths and depths are formed along the axial direction of the cylindrical body 2c on the outer peripheral surface of the cylindrical body 2c formed at the tip of the reduced diameter portion 2b. Then, a nipple 2 provided with five ribs 2, a die 3 having a resin discharge hole 3c through which the cylindrical body 2c of the nipple 2 can be inserted, a cylindrical body 2c of the nipple 2 and a resin discharge hole 3c, A cylindrical elongated body 10 having a flow path FR for circulating fluid on the outer periphery of the core material 7 using an extrusion molding apparatus 11 having an adjustment cap 12 capable of adjusting the positional relationship of Molded as follows.
In addition, the screw pitch of the adjustment cap 12 is set to 1 mm in the embodiment.

As the core material 7, a cylindrical long body made of polyacetal resin having a capillary structure and a diameter of 1.35 mm was used.
The core material 7 is obtained by coating a polyacetal resin once on the outer periphery of a core body having a capillary structure of φ0.85 to form a 0.25 mm thick coating layer.
As a polyacetal resin extruder, a small single screw extruder having a screw speed of 20 rpm, a cylinder temperature of 200 ° C., a flange temperature of 180 ° C., and a head temperature of 180 ° C. was used, and the take-up speed of the core material was 20 m / min. And the polyacetal resin was extruded.

<First embodiment>
Using an extrusion molding device 11 shown in FIG. 1, first, to form a primary coating layer R ₁ having a predetermined thickness a polyacetal resin on the outer periphery of the core material by coating once.
When forming the primary coating layer R _1, the relationship of the nipple 2 and the die 3, as shown in FIG. 7, the distal end surface of the rib 2d is rearwardly at least 0.75mm or more from the end face of the resin discharge hole 3c of the die 3 Goed to position.

Then, as shown cap 12 for adjustment of the extrusion molding device 11 shown in FIG. 3 was set to notch 12 a to the position A of 12 o'clock.
The distal end surface of the rib 2d of the tubular body 2c of the nipple 2 in the position A, 0 mm position in Fig. 7, i.e., the distal end surface of the rib 2d is located at the open end of the resin discharge portion 3c of the die 3 ing.

When the resin R is supplied into the cross head in this state, a part of the resin R flows from the slit S to the resin discharge hole 3a along the rib 2d.
At the same time, the resin R flows into the cylindrical body 2c through the slit S together with the air while flowing into the resin discharge hole 3a side.

As a result, as shown in FIG. 10, a secondary coating layer R ₂ having a required thickness is formed on the outer periphery of the primary coating layer R ₁ formed on the outer periphery of the core material 7, and the primary coating layer R A cylindrical long body 10 was obtained in contact with the outer periphery of _{1 and} in which five flow paths FR were continuously formed along the axial direction of the core material 7.
The average size of the obtained flow path FR was 0.1056 mm ² .

<Second embodiment>
A core material similar to that in Example 1 was used, and a polyacetal resin was coated once on the outer periphery by the same means as in Example ₁ to form a primary coating layer R1 having a required thickness.
Then, as illustrated adjustment cap 12 of the extrusion molding device 11 shown in FIG. 3, it rotated 90 ° counter-clockwise using the wrench was set notch 12 to the position B 9 o'clock.
The distal end surface of the rib 2d formed on the nipple 2 in this position B, the position of 0.25mm in Fig. 7, i.e., the distal end surface of the rib 2d is 0 from the opening end of the resin discharge portion 3c of the die 3. The position is set back by 25 mm.

When the resin R is supplied into the cross head in this state, a part of the resin R flows into the resin discharge hole 3a from the slit S along the rib 2d, and at the same time, the resin R is cylindrical with the air through the slit S. It flows into the resin discharge hole 3a while also flowing into the body 2c.
As a result, as shown in FIG. 11, the secondary coating layer R ₂ is formed in contact with the outer periphery of the primary coating layer R ₁ formed on the outer periphery of the core material 7 as in Example 1, and the primary coating layer R ₁ is formed. in contact with the outer periphery of the layer R _1, to obtain a cylindrical elongated body 10 continuously passage FR along the axial direction which is five formation of the core material.
The average size of the obtained flow path FR was 0.0656 mm ² .

<Third embodiment>
A core material similar to that in Example 1 was used, and a polyacetal resin was coated once on the outer periphery by the same means as in Example ₁ to form a primary coating layer R1 having a required thickness.

Then, as illustrated adjustment cap 12 of the extrusion molding device 11 shown in FIG. 3, rotated by 180 ° counter-clockwise using the wrench was set notch 12 at the position C of 6:00.
0.50mm tip surface of the nipple 2 formed ribs 2d in this position C, the position of 0.50mm in Fig. 7, i.e., the distal end surface of the rib 2d from the open end of the resin discharge portion 3c of the die 3 The position was set back.

When the resin R is supplied into the cross head in this state, a part of the resin R flows into the resin discharge hole 3a from the slit S along the rib 2d, and at the same time, the resin R is cylindrical with the air through the slit S. It flows into the resin discharge hole 3a while also flowing into the body 2c.
As a result, a secondary coating layer R ₂ is formed in contact with the outer periphery of the primary coating layer R ₁ formed on the outer periphery of the core material 7 as shown in FIG. in contact with the outer periphery of the layer R _1, to obtain a cylindrical elongated body 10 continuously flow path FR is which is 5 formed along the axial direction of the core material.
The average size of the obtained flow path FR was 0.0122 mm ² .

Incidentally, as shown extrusion apparatus 11 cap 12 for adjustment of the shown in FIG. 3, when using a wrench to 270 ° rotated counter-clockwise, to set the notch 12 to the position D 3 o'clock As described above, no flow path was formed in either the primary or secondary coating layer formed on the outer periphery of the core material 7.

The cylindrical elongated body manufactured in the present invention has one or a plurality of flow paths in parallel with the axis of the core material in the resin coating layer formed on the outer periphery of the solid or hollow core material. It can be used for various applications by flowing a fluid according to the application to the channel, or by sucking the fluid using the flow path, so that it can be used in a wide range of industries.

DESCRIPTION OF SYMBOLS 11 Extrusion molding apparatus 12 Adjustment cap 12a Notch part 12b Insertion part 12c Screw 2 Nipple 2a Nipple main body 2b Conical diameter reduction part 2c Cylindrical body 2d Rib 2e Air flow path 2f Resin flow path S Slit 3 Dies 3a Resin flow Road 3b Closed end face 3c Resin discharge hole 4 Cartridge 4a Screw 5 Crosshead 5a Resin supply port 7 Core material R Resin R ₁ Primary coating layer R ₂ Secondary coating layer

Claims (7)

A crosshead, a cartridge mounted in the crosshead, a nipple housed in the cartridge, a die housed in the cartridge and receiving a tip portion of the nipple, and a reciprocating engagement with the cartridge An extrusion molding apparatus for forming a flow path in a resin film constituting an outer layer of a core material, comprising an adjustment cap,
The dice
A frustoconical tip portion of the nipple can be received and has a space for forming a resin coating layer, and a small-diameter resin discharge hole is formed coaxially with the nipple at the center portion of the closed end surface,
The nipple is
While having a cylindrical body that can be fitted in the resin discharge hole formed in the die at the tip of the truncated cone-shaped reduced diameter portion continuous to the hollow cylindrical nipple body having a core material insertion portion therein , Having a slit for forming one or a plurality of ribs from the end face of the cylindrical body toward the truncated cone side,
The adjustment cap is
It is possible to adjust the positional relationship between the nipple and the die, and is in the shape of a cap nut having a core material insertion portion at the center,
By adjusting the positional relationship between the nipple and the resin discharge hole of the die that receives the nipple , the amount of resin flowing in the slit is adjusted, and a gap for forming a fluid flow path from the tip of the rib An extrusion apparatus characterized in that it is configured to form a portion. The dice
The extrusion molding apparatus according to claim 1, wherein a conical inner peripheral surface capable of forming a resin flow path is formed between the tip portion of the nipple and the truncated cone shape . The rib is
The extrusion molding apparatus according to claim 1 , wherein an air flow path that makes air flow favorable is formed on an inner peripheral surface thereof. The cylindrical body is
The extrusion molding apparatus according to claim 1 , wherein a resin flow path that makes a resin flow good is formed on an outer peripheral surface of a base portion of the slit. Single or plurality of slits coating resin flows is formed, the position of the die having a resin discharge hole for receiving the tubular portion and the nipple having a diameter of the tubular body, the tip of the cartridge containing the die The cross section of the fluid flow path provided in the resin coating layer of the outer layer of the core material by rotating and adjusting the adjustment cap that is screwed into the part and disposed on the outlet side of the resin discharge hole of the die The manufacturing method of the cylindrical elongate body characterized by controlling the magnitude | size of this. The cylindrical elongated body is
6. The method for producing a cylindrical elongated body according to claim 5, wherein the cross-sectional diameter is extremely fine with a diameter of 2 to 4 mm. The flow path is
Method of manufacturing a tubular elongated member according to claim 5 or 6 its cross-sectional area, characterized in that in the range of 0.01~0.15mm ^2.